Virtualization of data storage drives of an automated data storage library

ABSTRACT

Drive image providers of a virtualization system for an automated data storage library provide an image of a fixed plurality of virtual data storage drives with fixed identifications to a host application. A drive resource provider, at any one time, assigns any number “m” of a pool of “n” drives to the drive image providers, and “n”−“m” of the pool are freed and available for assignment. The drive resource provider responds to a triggering event requesting a drive, and dedicates one of the “n”−“m” drives of the pool to the virtual drive. The drive image provider characterizes and directs communication between the host and the dedicated drive as a fixed virtual drive; and prior to the dedication of a drive, characterizes the virtual drive to the requesting host application as “not ready”.

CROSS REFERENCE TO RELATED APPLICATION

Copending and coassigned U.S. patent application Ser. No. (TUC920010038-US2) filed on even date herewith relates to allocation of data storage drives of an automated data storage library.

FIELD OF THE INVENTION

This invention relates to data storage drives of an automated data storage library which stores portable data storage cartridges in storage shelves and transports the portable data storage cartridges between the storage shelves and the data storage drives for mounting and demounting the portable data storage cartridges at the data storage drives, and, more particularly, to the virtualization of those data storage drives with respect to host applications which communicate with the library.

BACKGROUND OF THE INVENTION

Automated data storage libraries are increasingly employed for storage of large quantities of data, typically data that is infrequently accessed by the host applications. The data is stored on portable data storage cartridges which are stored in storage shelves. Examples of portable data storage cartridges are cartridges containing a length of magnetic tape or containing an optical disk.

When the data is accessed by the library, an accessor robot operated by a robot control of the library, grips the desired portable data storage cartridge from the storage shelf at which it is stored and transports the portable data storage cartridge between the storage shelves and data storage drives for mounting and demounting the portable data storage cartridges at the data storage drives, and returning the portable data storage cartridge to the same or a different storage shelf.

Automated data storage libraries are sometimes arranged so that, even in the presence of multiple host applications, the library and its data storage drives appear to each host application as its own library and drives. In one example, a specific set of storage shelves and at least one data storage drive of the library is dedicated to each host application. Upon a request for data from the host application, the portable data storage cartridge having the requesting data is accessed by the accessor robot of the library, and delivered to a data storage drive dedicated to the host application for use by the host application. The host application can thus conduct a series of mounts on a known drive. This is very efficient from the standpoint of the host, since its drive is always available, and the drive addressing is direct and immediate. The library may also appear to be directly assigned to the host application, but the accessor robot is actually shared. It is less efficient from the standpoint of the drive usage in that, if each of the host applications is not constantly using its dedicated data storage drive(s), the drives are often idle. Since the drives are assigned to different host applications, no host application is able to “borrow” drives from another host application, and, for example, if all of the assigned drives are utilized and data on a different cartridge is needed, the host application may have to wait until the host application itself demounts one cartridge or releases one drive in order to access data on the other cartridge. Any “borrowing” of a drive from another host application would require reconfiguring at least the device drivers for both host applications, potentially requiring a re-IML of each host operating system or application. Should a host application grow in its needs, new drives cannot be assigned to that host application without reconfiguring at least the host application. Should a drive fail and need to be replaced, the host application may be unable to recover from the exception condition, especially if no other drive is available. It may be possible to limit the reconfiguration to a change of serial number if the drives are homogeneous in all other respects. Upgrading, exchange or sharing of heterogeneous drives (drives of at least one different characteristic) is prohibited without a major reconfiguration which will accommodate the different characteristics. Limited drive sharing may be provided by a host application that is partitioned amongst various host processors, but the partitions must constantly inform each other of their use of the drive so as to stay within synchronization, and sharing outside of the host application is not allowed.

In another example, the host applications are not allowed direct communication with a data storage drive. Rather, a “virtual” library is established which employs cache storage (typically disk drives) to store data received from host applications, acting as though the cache storage is a tape drive and is writing the data to tape. The data may be reaccessed while in the cache, called a “cache hit”. If not reaccessed, the library downloads the data from the cache storage to a cartridge employing a tape drive selected by the library. When data is requested by the host application, and it is not in cache, called a “cache miss”, the library employs a table to find the cartridge storing the data, operates the accessor robot to access the cartridge, finds an available tape drive, operates the accessor robot to mount the cartridge on the drive, reads the data from the cartridge and uploads the data to cache. From the standpoint of the library, the usage of the library components is efficient. However, cache storage is expensive and adds cost and complexity. The cache storage must be sufficiently large to handle large data sets and must have good staging and destaging algorithms to avoid excessive “cache miss” situations. The host applications communicate with the cache rather than directly with a drive, and any host application can contend for use of shared components, leading to less predictable performance.

SUMMARY OF THE INVENTION

An object of the present invention is to allow host applications to each gain access to one or more shared data storage drives of an automated data storage library, and have the appearance that the drives are dedicated to the host without requiring cache storage.

Another object of the present invention is to allow the addition, deletion or replacement of drives without requiring a reconfiguration of the host application device driver.

A virtualization system directs communication between host applications and physical data storage drives of an automated data storage library. The library stores a plurality of portable data storage cartridges in storage shelves and provides an accessor robot for transporting the portable data storage cartridges between the storage shelves and the data storage drives.

At least one drive image provider is coupled to the host application, providing at least one image of at least one virtual data storage drive to the host application, providing fixed identifications and fixed sets of responses to the host application for each of the virtual drives, and directing communication between the host application and data storage drives of a pool of “n” data storage drives of the automated data storage library.

A drive resource provider is coupled to the drive image providers. At any one time, the drive resource provider has assigned any number “m” of the pool of “n” physical data storage drives to the drive image providers, and “n”−“m” of the pool of data storage drives are indicated as freed and available for assignment. The drive resource provider responds to a triggering event requesting a virtual drive for the host application, dedicating one of the “n”−“m” data storage drives of the pool to the virtual drive, indicating the dedication for a drive image provider for the requesting host application as one of the fixed plurality of virtual drives.

The drive image provider characterizes the dedicated data storage drive to the requesting host application as one of the fixed virtual drives, and directs communication to the dedicated data storage drive by the requesting host application as the virtual drive.

Prior to the drive resource provider dedicating a drive, the drive image provider characterizes the virtual drive to the requesting host application as “not ready”. As an example, “not ready” comprises a reported state that no media is loaded in the drive.

In one embodiment, the triggering event comprises a request by the requesting host application to mount a selected one of the portable data storage cartridges at a virtual data storage drive. The drive resource provider indicates to the-library which one of the “n”−“m” data storage drives of the pool is the drive dedicated to the host application for mounting the selected portable data storage cartridge.

As an alternative embodiment, the triggering event comprises a “Reserve” request by the requesting host application for a virtual data storage drive of the drive image provider. The “Reserve” request is received by the drive image provider, notifying the drive resource provider as a request for a drive of the pool. The drive resource provider additionally indicates for the library that the dedicated data storage drive is dedicated to the requesting host application for mounting any portable data storage cartridge selected for the data storage drive as identified by the fixed identification as the virtual drive.

As a further alternative embodiment, the triggering event comprises a command by the requesting host application for a virtual data storage drive. The drive resource provider additionally indicates for the library that the dedicated data storage drive is dedicated to the requesting host application for mounting any portable data storage cartridge selected for the data storage drive as identified by the fixed identification as the virtual drive.

The drive resource provider responds to a detriggering event relating to the host application and designating a data storage drive dedicated to the detriggering host application, indicating the data storage drive is freed from the drive image provider, and adds the drive to the freed data storage drives of the pool. In one embodiment, the detriggering event comprises a command by the detriggering host application to demount the one of the portable data storage cartridges from the dedicated data storage drive, identified as one of the virtual data storage drives. In such case, the drive resource provider provides an indication for the library identifying the dedicated data storage drive as the virtual drive at which the portable data storage cartridge is mounted. In another embodiment, the detriggering event comprises a command by the detriggering host application to release the dedicated data storage drive, identified as one of the virtual data storage drive.

In a still further embodiment, the detriggering event comprises non-use of the dedicated data storage drive for a predetermined time-out period. Upon expiration of the predetermined time-out period, the drive resource provider determines whether one of the portable data storage cartridges remains mounted at the dedicated data storage drive, and notifies the library to demount the mounted portable data storage cartridge.

In another embodiment, the library comprises a plurality of virtual libraries, and at least one of the plurality of the virtual libraries is assigned a higher priority. Thus, upon “m”−“n” equaling zero, meaning that all of the data storage drives are dedicated, and upon a triggering event for a virtual drive of the higher priority virtual library, the drive resource provider deallocates a data storage drive from a lower priority virtual library, notifies the drive image provider of the deallocation, notifies the library to demount any portable data storage cartridge from the deallocated data storage drive, and dedicates the deallocated data storage drive to the virtual drive of the higher priority virtual library.

Additionally, data storage drives may be added, deleted, or exchanged in the pool of data storage drives of the drive resource provider, but the drive image provider characterizes the virtual drives as unchanged.

In one embodiment, the drive resource provider communicates with the drive image provider employing a drive image table having a list of the virtual data storage drives comprising the image, and indicating the data storage drives of the pool dedicated as the virtual drives.

For a fuller understanding of the present invention, reference should be made to the following detailed description taken in conjunction with the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a diagrammatic representation of a virtualization system in accordance with the present invention;

FIG. 2 is an isometric view of an automated data storage library which may implement embodiments of the present invention;

FIG. 3 is a block diagram of the automated data storage library of FIG. 2, together with host applications and components intermediate the host applications and the automated data storage library which may implement embodiments of the present invention;

FIGS. 4A and 4B are respectively top and end views of an exemplary portable data storage cartridge which may be stored in the storage shelves of the automated data storage library of FIGS. 2 and 3;

FIGS. 5A and 5B are diagrammatic illustrations of exemplary drive image tables in accordance with the present invention;

FIG. 6 is a diagrammatic illustration of an exemplary drive table in accordance with the present invention;

FIG. 7 is a diagrammatic illustration of an exemplary library image table in accordance with the present invention;

FIG. 8 is a flow chart depicting an embodiment of the method of the present invention for configuring or altering the configuration of the drives of the automated data storage library of FIGS. 2 and 3;

FIG. 9 is a flow chart depicting an embodiment of the method of the present invention for the drive image provider of FIG. 1;

FIGS. 10A and 10B are a flow chart depicting an embodiment of the method of the present invention for the drive resource provider of FIG. 1 for triggering events;

FIG. 11 is a flow chart depicting an embodiment of the method of the present invention for the drive resource provider of FIG. 1 for detriggering events; and

FIGS. 12A, 12B and 12C are flow charts depicting an alternative embodiment of the present invention for the drive resource provider of FIG. 1 for locking data storage drives.

DETAILED DESCRIPTION OF THE INVENTION

This invention is described in preferred embodiments in the following description with reference to the Figures, in which like numbers represent the same or similar elements. While this invention is described in terms of the best mode for achieving this invention's objectives, it will be appreciated by those skilled in the art that variations may be accomplished in view of these teachings without deviating from the spirit or scope of the invention.

Referring to FIGS. 1-3, an embodiment of a virtualization system 10 is illustrated which directs communication between host applications, such as host applications 11, 12, and data storage drives 15 of an automated data storage library 17. The library stores a plurality of portable data storage cartridges 14 in storage shelves 16 and provides an accessor robot 18, 20 for transporting the portable data storage cartridges between the storage shelves and the data storage drives.

At least one drive image provider 30 is coupled to one or more host applications 11, 12, and provides an image of at least one fixed virtual data storage drive to each host application, while actually directing communication between the host application and data storage drives of a pool of “n” data storage drives 15 of the automated data storage library. The drives 15 of the library are thus shared between the host applications. The drive image provider depicts the image in communications with the host by employing fixed identifications and fixed sets of responses to the host application for each of the virtual drives, such that the host application is provided with the appearance that all of the host's virtual drives are dedicated to the host all of the time. Further, the underlying physical drives may be different at various accesses, and drives may be added, deleted or replaced, all without requiring a reconfiguration of the host application device driver.

A drive resource provider 35 is coupled to the drive image providers 30. At any one time, the drive resource provider has assigned any number “m” of the pool of “n” data storage drives to the drive image providers, and “n”−“m” of the pool of data storage drives are indicated as freed and available for assignment.

The drive resource provider 35 responds to a triggering event requesting a drive for the host application virtual drive, and dedicates one of the “n”−“m” data storage drives of the pool as the virtual drive, indicating the dedication for the drive image provider for the requesting host application as one of the fixed virtual drives.

The drive image provider 30 characterizes the dedicated data storage drive to the requesting host application as one of the fixed virtual drives, and directs communication to the dedicated data storage drive 15 by the requesting host application 11, 12 as the virtual drive.

Prior to dedication of a physical drive as a virtual drive, the drive image provider 30 responds to a command requiring a physical drive, characterizing the virtual drive to the requesting host application as “not ready”. As an example, “not ready” comprises a reported state that no media is loaded in the drive.

In one example, one or more library image providers 43 may also be provided for virtual libraries, and will comprise a set of the virtual drives and a set of the storage shelves 16, which are defined by a library resource provider 39. Data storage drives 15 are shared between virtual libraries, but storage shelves 16 are preferably separate.

A host application 11, 12 may comprise a host processor, such as an IBM RS/6000 or an IBM eServer pSeries processor, and all the applications running on the host processor, or may comprise one of multiple applications running on the host processor. Thus, the host applications are depicted as each comprising a processing system having a processor 36 and storage 38.

The automated data storage library 17, as an example, comprises an automated tape cartridge storage and retrieval library for storing and accessing data storage media comprising physical volumes of magnetic tape cartridges, such as an IBM 3584. Alternatively, the automated data storage library 17 may comprise an optical storage and retrieval library or a tape cassette library, etc., each defined herein as storing portable data storage cartridges. The data storage drives 15 read and/or write data on the media, and may comprise a processor. The library further comprises a robot controller 41 for operating the accessor robot 18, 20, and a library manager 40. The accessor robot 18, 20 comprises a gripper 20 for engaging a selected portable data storage cartridge 14, and an accessor 18 for moving the gripper between a storage shelf 16 and a drive 15, or between storage shelves. The accessor robot 18, 20 may also comprise a bar code scanner 22, or similar vision system, mounted on the gripper 20, to “read” identifying cartridge labels. The data storage drives 15 can be optical disk drives or magnetic tape drives and the portable data storage cartridges can comprise cartridges or cassettes containing optical or magnetic media, respectively, or any other removable storage.

The robot controller 41 and library manager 40, comprise at least one computer processor and associated storage, and are coupled to an input/output interface 42 and a terminal 28. The computer processor may comprise, for example, an IBM RS/6000 processor. Alternatively, robot controller 41 and library manager 40 may each comprise a computer processor, and the computer processors are interconnected. In the example, library manager 40 comprises a computer processor 45 and associated storage 46. The terminal 28 may comprise a station for reading a data storage medium, such as a floppy disk or CD-ROM.

The library manager 40 is coupled with, and controls the load/unload and related actions of, the drives 15, and the library manager 40 is coupled with, and coordinates the operation of the robot controller 41. The library manager is coupled through the interface 42 to the host applications 11, 12. The library manager 24 has a library manager database which is stored in storage 46 (typically one or more hard disk drives or flash EEPROM) for tables and programs. Data access commands and information to be recorded on, or to be read from, selected portable data storage cartridges 14 are transmitted between the drives 15 and the host applications as directed by the data image provider 30. The library manager 40 defines each portable data storage cartridge in terms of its identifier, which is typically a volume serial number, or VOLSER, or, alternatively, in terms of its location.

The host applications 11, 12 are typically coupled to the library 17 by one or more components intermediate the host application and the automated data storage library.

An example of an intermediate component is a host bus adapter 50. In one example, the host bus adapter 50 comprises interfaces 52 and 53 which each interfaces with the appropriate connections to couple to the library or to other intermediate components, and to the host applications 11, 12, such as PCI, ESCON, FICON, SCSI, FIBER CHANNEL, etc. The adapter comprises a processor 54 and non-volatile memory 55, and suitable buffers and interconnections. An example of a host bus adapter 50 comprises an IBM eserver pSeries Gigabit Fibre Channel Adapter. Host application 12 is shown with an interface 53 which may comprise an adapter.

Another example of an intermediate component comprises a gateway or router 56 having a plurality of interfaces 57 with the appropriate connections to interconnecting a number of processors in a network, such as discussed above. The gateway or router comprises a processor 58 with a non-volatile memory 59 for storing the operating system, etc. An example of a gateway or router is the IBM 2108 SAN Data Gateway. Other suitable terminology for the present adapter, router or gateway are “controller”, “director” or “intelligent switch”, and those of skill in the art may envision other applications.

The processors 54, 58 may comprise microprocessors, such as the Intel i960.

In accordance with the present invention, the drive image providers 30 and/or the drive resource provider 35 may be embedded in any of a host application 11, 12, an intermediate component 50, 56, or the automated data storage library 17. As one example, the drive image providers 30 are each incorporated into a device driver of the associated host application 11, 12, and the drive resource provider is incorporated into a component 56 intermediate the host applications and the automated data storage library 17. The drive resource provider must be at a component coupled to each of the hosts, or host bus adapters of hosts, having a drive image provider. As still another example, the drive image provider(s) 30 comprise a component 50, 56 intermediate the host application(s) 11, 12 and the automated data storage library 17, and the drive resource provider 35 comprises a component 56 intermediate the host bus adapter 50 or host and the library 17. As a further example, drive image providers 30 comprise device drivers of the associated host applications 11, 12, and the drive resource provider 35 comprises a component of the automated data storage library 17, such as the library manager 40. A still further example comprises the drive image provider(s) 30 as incorporated in a component 50, 56 intermediate the host application and the automated data storage library, and the drive resource provider 35 comprises a component of the automated data storage library 17.

The library image provider(s) 43 and the library resource provider 39 are preferably both incorporated into the automated data storage library 17.

Each of the processors 36 of the host applications 11, 12, processors 54, 58 of the intermediate components 50, 56, and processor 45 of the library manager 40 of the library, may be provided with an operating system and application programs, and may comprise programs for operating in accordance with the present invention. Each processor may be provided with a database, respectively, 38, 55, 59, 46, which includes storage (typically non-volatile memory or one or more hard disk drives) for tables and programs. The application programs may comprise one or more computer program products, comprising computer readable program code. The computer program product of the present invention may be supplied with an application program and stored in the provided storage, may be supplied with a diskette or CD-ROM at terminal 28, and comprises an article of manufacture, may be received from one of the host systems 11, 12, may be received from the network, or may be received by other similar means. The requirement for the storage media or memories is that they store digital representations of computer executable instructions. The computer readable program code operates the devices through their computer processor or processors.

In FIGS. 4A and 4B, an example of a portable data storage cartridge 14 is illustrated, which, for example, comprises a magnetic tape cartridge. The cartridge 14 has an identifying label 60 on an outer edge 61.

FIGS. 5A and 5B illustrate examples of drive image tables 70, 71 that are generated and maintained by the drive resource provider 35 and which are provided to the drive image providers 30 of FIG. 1, in which the drive resource provider maps the allocated and dedicated drives of the pool of data storage drives to the virtual drives of each host application. The drive image tables may be read by the drive image providers periodically from the drive resource provider and updated, for example, each half second, or each drive image provider may access the associated drive image table as needed. The drive image provider does not need to refresh the table each time, but rather may look for any changes.

The drive image table includes a list 75 of the virtual drives that the drive image provider is to report and provide responses for. As an example, in SCSI terms, the list 75 may comprise a fixed address such as a tape drive LUN identifier for each of the virtual drives. The drive image provider provides an image to a host application of one or more virtual data storage drives in fixed terms, and those drives are identified by means of the list 75. The fixed list is supplemented by an identification of the characteristics of each virtual drive 76 so that the drive resource provider may provide fixed identifications and fixed sets of responses to the host application for each of the virtual drives. As one example, the characteristics may include an unique serial number for the virtual drive. As a further example, the characterization may comprise the same address for the virtual drive. As an additional example, the virtual drive may be provided with characteristics which include a type or manufacturer designation and a model number. This will allow the drive resource provider to determine the fixed set of responses from its database. As an alternative embodiment, the drive image table of the drive resource provider may comprise only an identifier 75 for each virtual drive, and the drive image provider may maintain the characteristics 76 for each virtual drive.

As the drive resource provider dedicates drives from the pool of physical drives of the library to the drive image provider for the host application, those drives are also identified 77, for example, by LUN, in SCSI terms. In the illustrated example, the “*” represents an indication that no physical drive is currently assigned virtual drive. Also, a “W” represents that a physical drive will be assigned, but none is currently assigned, as will be discussed. Optionally, the drive resource provider may also provide the characteristics 78 of each assigned physical drive, such as a serial number, type, manufacturer designation and/or model number.

Referring additionally to FIG. 6, the drive resource provider 35 and/or the library resource provider 39 of FIG. 1 maintains a drive table 80 of the physical drives 81 and their current assignment or status 82. Preferably, the table 80 also includes the characteristics 83 of each of the physical drives, as above.

Referring additionally to FIG. 7, the library 17 of FIGS. 2 and 3 may be arranged to be directly coupled to the host applications and receive, for example, requests for the library to mount identified portable data storage cartridges 14 from storage shelves 16 at identified virtual drives. To accommodate these requests, the library comprises at least one library image table 85. The table identifies the virtual libraries 90, and the virtual drives 87 dedicated to each virtual library. Additionally, the library may indicate the priority 88 of the virtual library, and which virtual library or virtual drive is authorized 89 to use a spare drive. This information is presented to the host applications by means of the library image provider 43 of FIG. 1.

Each virtual library is assigned a set of the storage shelves 16. The same virtual library may be shared by multiple host applications or may comprise a separate virtual library for each host application, or there may be a mix. Table 85 identifies the virtual libraries in column 90, and the set of storage shelves 16 of FIGS. 2 and 3 assigned to each virtual library are identified in column 91. As is known to those of skill in the art, the storage shelves of an automated data storage library may be partitioned by the library manager such that each virtual library is assigned a specific set of storage shelves, such as storage shelves 92-96 in FIG. 3. The virtual libraries are arranged by the library resource provider 39 of FIG. 1. Preferably, the virtual libraries, as well as the host applications, share all or most of the physical drives 15 of the library 17 of FIGS. 2 and 3, as depicted in column 97. Certain data storage drives may be withheld from a pool of “n” drives for a virtual library as being of a type that does not match the requirement of the virtual drives. One example is a low speed drive useful in only particular situations. Another example is a streaming drive not useable for small data records.

In the illustrated tables 70, 71, 80 and 85 of FIGS. 5A, 5B, 6 and 7, as examples, physical drive “DR3” is assigned in the drive image table 70 as virtual drive “AA”, and is in virtual library “0”. The drive will be deallocated when released by the host application or when the host application issues a command to demount a portable data storage cartridge mounted in the drive. Physical drive “DR1” is assigned in drive image table 71 for virtual library “1”, and is dedicated as virtual drive “EE”. The “(L)” is an indication that the physical drive is locked to the host application as the virtual drive until specifically released by the host application, and the drive will not be deallocated when the host application issues a command to demount a portable data storage cartridge mounted in the drive.

The relative priorities 88 of the virtual libraries means that, in the circumstance where “n”−“m” data storage drives of the pool equals zero, indicating that all drives of the pool have been assigned, a higher priority host application, e.g., priority “0”, may take a drive already dedicated to a lower priority host application, e.g., priority “1”. With the use of virtual libraries, the tables depict the option of assigning physical drives 97 to virtual libraries 90, thereby defining a pool of data storage drives. If only one library was employed, all the data storage drives except spares constitute the pool of drives. Physical drive “DR2” is, at the moment, unassigned to any virtual drive, and is indicated as “FREED” and available for assignment. Physical drive “DR7” is reserved as a “SPARE” drive, and can only be used in the circumstance where “n”−“m” data storage drives of the pool equals zero, indicating that all drives of the pool have been assigned, and, either there is no priority reallocation, or all drives that could be reallocated have high priority assignments. If spares are authorized as shown by column 89, the drive resource provider then allocates one of the spare drives to the request. Alternatively, the drive resource provider waits a predetermined time period, and, if during the predetermined time period a request for deallocation of a data storage drive and demount of any portable data storage cartridge at the deallocated data storage drive completes, allocates the deallocated data storage drive to the request; else, subsequent to expiration of the time period, the drive resource provider allocates the spare data storage drive to the request.

Subsequent to the allocation of the spare data storage drive, the drive resource provider posts a message indicating use of the spare data storage drive. The posted message may comprise a notification to a system manager that action may be taken to transfer a spare data storage drive to the pool. As an example, transferring a spare drive to the pool will result in an increased cost for the library. If the transfer is made, the drive resource provider adds the spare data storage drive to the pool, deleting the drive as a spare data storage drive.

As an incentive, the posted message may additionally comprise a notification that failure to transfer the spare drive to the pool will result in future unavailability of spare data storage drives, and the drive resource provider, upon absence of a request to transfer at least one spare data storage drive to the pool, deletes the assignment of the plurality of library data storage drives as spare drives at least to one virtual library, such that the assigned spare drives become unassigned to the virtual library or, alternatively, in the library system.

In drive image table 70 of virtual library 0, virtual drive “BB” has no dedicated data storage drive, and is in the circumstance that the host application requires a physical drive. However, no physical drive, either a spare drive or a drive from a lower priority virtual library or lower priority virtual drive is available. Thus, the “W” means that there will be a wait until a data storage drive becomes available in the normal operation of the library.

FIG. 8 illustrates an embodiment of the method for configuring the data storage drives 15 of the library 17 of FIGS. 2 and 3, or of configuring the virtual libraries.

The configuration begins at step 100 in a startup or initialization of the library. Alternatively, a physical drive may be added, deleted or replaced and the reconfiguration begun at step 101. Still alternatively, a system operator, having used a spare data storage drive and received the message as discussed above, may choose to add one or more of the spare drives to a pool of drives, beginning at step 102. If the system operator was presented with the choice of employing the spare drive in a pool or of losing the drive as a spare and chooses to lose the drive (an unlikely scenario), step 102 could also provide a reassignment of the formerly spare drive or drives to an “unassigned” status. No reconfiguration of the library is actually required in this circumstance.

Step 105 may be employed for the situation where the use of virtual libraries is optional, and determines whether virtual libraries implemented. If virtual libraries are implemented, “YES”, step 106 determines the next virtual library to be configured. If virtual libraries are not implemented, “NO”, the physical library will be configured for a single set of virtual drives. The process may be conducted by the library resource provider and/or the drive resource provider, and the library resource provider is required if virtual libraries are implemented. If virtual libraries are not implemented, the library image table 85 of FIG. 7 will comprise only a single library, eliminating column 90.

In step 110, the physical drives available to the library are determined. This information may be provided by the system operator or may comprise a default, for example, in which all of the number of drives are shared by all the virtual libraries. In step 111, the spare drives are identified. The spare drives may be established at the time that the library 17 of FIGS. 2 and 3 is sold or installed, or may be set by the system operator to control the price paid for the library. The number of physical drives “n” in the pool of drives for the virtual library is the number of available physical drives PD less the number of spare drives SD.

In step 120, the number of virtual drives and the fixed identification of each of the virtual drives are determined, for example, from the responsible system operator, or from the device driver, for communication with each host application. This comprises the identifier to be employed by the host application to address the fixed virtual drives, and as illustrated in column of FIGS. 5A and 5B, in column 87 of FIG. 7, and is used for the allocation shown in column 82 of FIG. 6. The characterization information 76, 83 may also be obtained at this point. In step 115, the relative priorities of the virtual libraries are determined, for example, by the system operator. As an alternative, relative priorities may be determined for the virtual drives. The resultant relative priorities are posted in column 88 of FIG. 7. Then, in step 121, the drive resource provider arranges the drive image table(s) 70, 71 for each drive image provider. The master drive image tables are maintained in the drive resource provider, mapping the allocated and dedicated drives of the pool of data storage drives to the virtual drives of each host application. As discussed above, the drive image tables may be accessed and refreshed or updated by the drive image providers periodically from the drive resource provider, or each drive image provider may access the associated drive image table as needed.

In step 125, the library resource provider determines whether all of the virtual libraries have been configured. If so, or if virtual libraries have not been implemented, the process is ended as illustrated by step 126. If not all of the virtual libraries have been configured, the process cycles back to step 106 to begin configuration of the next virtual library.

FIG. 9 illustrates the process of the drive image provider 30 of FIG. 1 when a host application provides a command for a virtual drive at step 135. Examples of events are an INQUIRY command; a SEARCH command to search for specific data from a mounted portable data storage cartridge; a READ command to read data from a mounted portable data storage cartridge; a WRITE command to write data on a mounted portable data storage cartridge; a RESERVE command to reserve a data storage drive for future use; a RELEASE command to release a reserved data storage drive; or other similar types of commands.

The drive image provider, in steps 141 and 143, determines whether the command received from the host application constitutes a triggering event or a detriggering event. If the command constitutes a triggering event, the drive image provider, in step 144, notifies the drive resource provider of the event and identifies the virtual drive and may identify the host application. If the command constitutes a detriggering event, the drive image provider, in step 149, notifies the drive resource provider of the event and identifies the virtual drive and may identify the host application.

In step 140, the drive image provider looks up the virtual drive in the drive image table 70, 71 of FIGS. 5A, 5B for the virtual library.

Step 136 determines whether the command of step 135 requires a physical drive to complete the response to the event. For example, SEARCH, READ, and WRITE commands all require a physical drive. An INQUIRY command does not require a physical drive, and a response may be provided by the drive image provider without a drive, and the response is provided in step 137. The drive image provider responds as the addressed virtual drive, and employs the characteristics of the drive from the drive image table 70, 71 of FIGS. 5A, 5B, or equivalent. SEARCH, READ, and WRITE commands will be provided by a host application if a portable data storage cartridge is mounted in the dedicated physical drive, thus, a MOUNT command will have been provided to the library.

Commands that lead to the allocation and dedication of a physical drive to a virtual drive are called triggering events, and comprise RESERVE commands and other commands having the effect of a request for a drive, such as an “are you there” type of command. Commands that lead to the deallocation of a physical drive are called detriggering events, and comprise RELEASE commands and other commands having the effect of releasing a drive. RESERVE and RELEASE commands, and commands requesting or releasing a virtual drive are received by the drive image provider.

In step 142, the drive image provider determines from the drive image table whether a physical drive is dedicated to the virtual drive of the command. If a physical drive is dedicated to the virtual drive, “YES”, the drive image provider, in step 143, directs communication between the requesting host application and the dedicated data storage drive of the pool of “n” data storage drives of the automated data storage library. The communication is destaged and translated as necessary so that, from the standpoint of the host application, the communication appears to be between the host application and the virtual drive. The communication comprises all that is expected to follow as the result of the command, and will include the transfer of data, etc., with any expected headers, etc.

If the host application has issued a MOUNT command to the library, it then is likely to issue a SEARCH, etc., command to the virtual drive. The command may be received prior to the update of the drive image table by the drive resource provider. Hence, the drive image provider, prior to drive resource provider dedicating a physical data storage drive from the pool, in step 142, determines from the drive image table that no physical drive has been dedicated to the requesting host application, and the drive image provider responds to the requesting host application with a fake completion response in step 150 having the effect of informing the host application that the request has been received, and that the virtual drive is “not ready” to complete any command requiring a mounted portable data storage cartridge. The drive image provider reports two types of “not ready” fake completion responses. In one example, if the virtual drive is indicated in the drive image table as waiting “w”, the drive image provider reports that the virtual drive is “coming ready”. In an alternative example, the drive image provider reports “cartridge not present” at the virtual drive. In either case, the “not ready” response is not an indication that any requested work is complete. Rather, it is a form of command rejection based on one of the two reasons.

Upon step 136 indicating that no physical drive is required, such as an INQUIRY, RESERVE, or RELEASE command, etc., as discussed above, the drive image provider responds as the addressed virtual drive, employing the characteristics of the virtual drive from the drive image table 70, 71 of FIGS. 5A, 5B.

Referring to FIGS. 10A and 10B, step 160 refers to the occurrence of a triggering event, such as receipt of a MOUNT command 161, a RESERVE command 162, or a request 163 for a drive, such as an “are you there” request, with or without a request to lock the drive. The request will have been received by the drive image provider and the drive resource provider notified in step 144 of FIG. 9, or, if a MOUNT command received directly by the library, or virtual library, it is provided to the drive resource provider as a direct triggering event.

In step 170, the drive resource provider determines the virtual drive for which the triggering event is intended by the requesting host. This typically is determined from the notification or command itself. In step 172, the drive resource provider determines the drive image table 70, 71 of FIGS. 5A and 5B for the virtual drive.

Having determined the drive image table, the drive resource provider accesses the drive image table in step 175. In step 176, the drive resource provider determines from the drive image table whether a physical drive is dedicated to the virtual drive of the event. If the drive has been dedicated, the process ends in step 177 and the drive image provider is directing communication between the requesting host application and the data storage drive as the virtual drive, as illustrated in step 143 of FIG. 9.

If no drive has been dedicated, the drive resource provider, in step 180, determines whether “n”−“m” is greater than zero, e.g., from the drive table 80 in FIG. 6. If “n”−“m” is greater than zero, “YES”, not all of the physical drives have been allocated and a physical drive is therefore available for allocation and dedication to the requesting host application. As discussed above, the pool of drives may comprise only data storage drives that are compatible with the characteristics of the virtual drive. As an example, many of the physical drives may be streaming drives and the requested virtual drive may instead be a stop-start drive.

If a physical drive is available, such that “n”−“m”>0, the drive resource provider, in step 185, allocates the physical drive to the virtual drive, dedicating the physical drive for the requesting host application. If more than one drive is available, the selection of the specific drive may be made in accordance with any appropriate algorithm. As one example, the drive having the closest characteristics to the virtual drive may be selected. As another example, the drive having been idle the longest may be selected. The drive resource provider thus increments “m” to the value “m”+1.

Upon allocating the physical data storage drive in step 185, the drive resource provider updates the drive image table 70, 71 of FIG. 5A or 5B. As discussed above, the drive resource provider thus maps the allocated and dedicated drives of the pool of data storage drives to the virtual drives of each host application. The updated drive image tables may be accessed by the drive image providers periodically from the drive resource provider, or each drive image provider may access the associated drive image table as needed. The drive table 80 of FIG. 6 is also updated and may comprise the allocation of the drive of step 185. In step 187, the drive resource provider indicates to the library to release any hold of a mount of a portable data storage cartridge relative to the request, as will be discussed.

If no physical data storage drive is available, as indicated by step 180 determining that “n”−“m” is equal to zero, “NO”, indicating that a request has been received for a data storage drive when all of the data storage drives of the pool are allocated, the drive resource provider, in step 190, indicates to the library to hold any mount of a portable data storage cartridge relative to the request. In this manner, the library does not initiate a mount, which would begin movement of the accessor robot to select the desired portable data storage cartridge, when no physical drive is available at which to mount the cartridge. Prevention of a mount without a drive prevents a potential lockup of the accessor robot with a cartridge to be mounted on one drive, while the same accessor robot may be required to demount another cartridge so as to make the drive of the demount available. Additionally, a fake completion response is provided to the mount request, which prevents a potential “command” lockup, in the instance where commands can only be dealt with in order. Once a drive is available and any cartridge has been demounted, the mount is released, in step 187. If step 180 indicates that no drive is allocated, the drive resource provider, in step 280, posts an indication “W” in the drive image table (e.g., table 70 of FIG. 5A) for the drive image provider indicating that the drive resource provider is waiting for a freed drive.

Various optional alternatives may be employed to allocate a physical drive, rather than just waiting for a presently allocated drive to be deallocated. These alternatives are discussed hereinafter, and may be implemented in any order.

If step 180 indicates that no drive is available, connector 208 leads to FIG. 10B and to step 210. Step 210 relates to the situation in which virtual libraries or virtual drives are assigned relative priorities, as depicted in column 88 of library image table 85 of FIG. 7. Thus, with a plurality of virtual libraries, where at least one of the virtual libraries has a higher priority than other of the virtual libraries, the drive resource provider, in step 210 determines the priority of the virtual library or the requested virtual drive, and whether the requesting virtual library or virtual drive is of the higher priority. If the requesting virtual library or virtual drive is of the higher priority, the drive resource provider, in step 211, selects a data storage drive from a lower priority virtual library. In step 212, the drive resource provider deallocates the selected data storage drive from the drive image table of the lower priority virtual library, notifies the drive image provider of the deallocation, and notifies the library to demount, in step 215, any portable data storage cartridge from the deallocated data storage drive. The drive image provider, in step 216, characterizes the virtual drive of the deallocated data storage drive to its host application as “not ready”. In step 220, the drive resource provider allocates the deallocated data storage drive for the higher priority virtual library. Connector 222 leads to step 186, where the drive is dedicated to the virtual drive of the requesting host application in the drive image table, and any hold of a mount is released in step 187. Any work gueued in step 150 by the drive image provider is dequeued as the result of steps 185, 186 and 187.

As discussed above, the drive resource provider may additionally assign at least one of the plurality of library data storage drives as spare drives, outside of any pool. Then, the drive resource provider may allocate a spare drive to the request. As one example, spare drives may be employed if no physical drives are assigned in lower priority situations. Alternatively, a spare drive may be requested only for high priority virtual libraries. Thus, if step 210 determines that the requesting virtual library or virtual drive is of high priority, step 230 determines whether use of a spare drive is authorized. Whether or not priority of the host application plays part in the determination, the authorization of spares may be determined, for example, from column 89 of library image table 85 of FIG. 7.

Even though spares may be authorized, their use may be limited. As one example, a time-out is set in step 240, so as to allow time for a data storage drive to be deallocated and freed, as detected by step 243. If a drive is freed as indicated by step 243, connector 205 leads to step 185 of FIG. 10A to allocate the freed drive. If no drive is freed, as indicated by step 243, step 245 determines whether the time-out period has expired. If not, “NO”, the process cycles back to step 243 to wait for a freed drive.

If the time-out period has expired, still another limitation on use of a spare may be employed. As one example, the use of spare drives may be limited to a predetermined number of times. As will be discussed, the system operator may be requested to add drives to the pool of “n” drives and prevented from unlimited use of spare drives. Specifically, in step 253, the drive resource provider increments a count each instance the request for a spare is received when all of the data storage drives of the pool are allocated. In step 254, the drive resource provider compares the incremented count to a predetermined limit, and, upon the incremented count being less than the predetermined limit, in step 255, allocates the spare data storage drive to the virtual library of the request. The drive table 80 of FIG. 6 and the library image table 85 of FIG. 7 are updated, moving the drive from a spare to a freed drive, temporarily incrementing the pool of drives “n” to a value of “n”+1, and assigning the drive to the virtual library of the request in column 97 of table 85. Connector 205 leads to step 185 of FIG. 10A for allocation of the now freed drive to the virtual drive of the requesting host application.

As an option, the drive resource provider additionally, subsequent to the allocation of the spare data storage drive, in step 260, posts a message indicating use of the spare data storage drive. The posted message, in one embodiment, comprises a notification to a system manager that action may be taken to transfer a spare data storage drive to the pool. As an example, transferring a spare drive to the pool will result in an increased cost for the library. If the transfer is made, the drive resource provider permanently adds the spare data storage drive to the pool, deleting the drive as a spare data storage drive.

In another embodiment, as an incentive, the posted message additionally comprises a notification that failure to transfer the spare drive to the pool will result in future unavailability of spare data storage drives, and the drive resource provider, upon absence of a request to transfer at least one spare data storage drive to the pool, deletes the assignment of the data storage drives as a spare drive, such that the assigned spare drive becomes unassigned. As discussed above, the uses of spare drives may be limited by the predetermined limit of step 254.

In the event that no spare drive is authorized in step 230, or that the incremented count of step 253 has reached the predetermined limit of step 254, the drive resource provider, in step 282, awaits a request for deallocation of a data storage drive and demount of any portable data storage cartridge at the deallocated data storage drive, freeing the data storage drive. If no drive is freed, as determined by step 282, the process continues to loop. Upon deallocation of a drive, step 282 leads to connector 205 of FIG. 10A for allocation of the deallocated data storage drive to the virtual drive for the host application requesting the drive in step 185, and indicating to the library to release the hold of any mount relative to the request in step 187.

In addition to releasing any held library mount, the drive resource provider provides an indication of the dedicated physical data storage drive at which any held or any future mount is to be executed. The indication comprises the posting to the drive table 80 of FIG. 6, which is accessed by the library. As a supplemental alternative for a release of a held mount, the indication of the dedicated physical data storage drive is provided with the release indication communicated to the library.

FIG. 11 relates to detriggering events of step 300. One example of a detriggering event comprises non-use of a dedicated data storage drive for a predetermined time-out period. In one embodiment, the completion of a function comprising a usage of a drive is identified in step 310, and, in step 311, resets a timer for that drive. Then, step 312 continues to track the timer and indicates if the time period has expired.

Other detriggering events comprise a DEMOUNT request 315 to demount the cartridge from the virtual drive and move the cartridge to another point, such as a storage shelf; a RELEASE command 316 to release a reserved virtual data storage drive; and a drive release indication 317. As discussed above, a DEMOUNT command is typically provided to the library and is not a command received by the drive image provider in step 135 of FIG. 9. The library, upon receiving the DEMOUNT command, determines the physical data storage drive dedicated to the virtual drive, initiates the demount, and informs the data resource provider of the command. A RELEASE command or a command requesting release of a virtual drive is received by the drive image provider in step 135 of FIG. 9. The drive image provider determines in step 143 that it is a detriggering event; and notifies the drive resource provider in step 149. In step 320 of FIG. 11, the drive resource provider determines the virtual drive for which the detriggering event is intended by the requesting host. This typically is determined from the command itself.

Step 325 determines whether a portable data storage cartridge is mounted in the drive. This may be determined, for example, from the library processor 45 of FIG. 1. A DEMOUNT command will have resulted in a demount of the portable cartridge by the accessor robot, such that step 325 indicates that no cartridge is mounted in the drive. The other detriggering events may not occur with a portable cartridge mounted in a drive and may not comprise a demount. If a cartridge is mounted in the drive, the drive resource provider indicates to the library that the cartridge is to be demounted in step 326.

In step 330, the drive resource provider determines the drive image table 70, 71 of FIG. 5A or 5B for the virtual drive, or for the physical drive if steps 310-312 employ the physical drive.

The drive resource provider then, in step 331, deallocates the drive from the virtual drive for the host application. The drive resource provider, in step 343, then indicates that the drive is freed, decrementing “m” to “m”−1. Optionally, if spare drives are employed, step 340 determines whether the deallocated drive was shared drive. If so, step 341 returns the drive to its original status, decrementing “n” to “n”−1. If the drive was a spare, the system operator may subsequently respond to the message of step 260 of FIG. 10B and add one or more spare drives to the pool. If the drive was not a spare drive, the drive resource provider proceeds directly to step 345. In step 345, the tables are updated, either returning the drive to its original status as a spare drive in drive table 80 of FIG. 6, or indicating the drive as freed in the drive table of FIG. 6.

FIGS. 12A-12C represent locking and unlocking a data storage drive to a virtual library. Step 400 of FIG. 12A represents a triggering event 160 of FIG. 10A in which a drive is requested with a lock. Step 401 is equivalent to step 185 of FIG. 10A for dedicating the drive to the virtual drive, and additionally comprises adding the “lock” to the drive table, as illustrated by drive “DR1” of drive table 80 of FIG. 6.

Step 410 of FIG. 12B represents a detriggering event 300 of FIG. 11 in which a drive is released by the host application with a release of the lock. Step 411 may occur immediately subsequent to step 300, and comprises a determination whether the command includes a release of the lock. If so, the lock is released by the drive resource provider, in step 412, at the drive table 80 of FIG. 6.

Step 420 represents a detriggering event 300 of FIG. 11 which does not comprise a release of a lock, such as a DEMOUNT command. Step 421 determines whether the drive is locked, referring, for example, to the drive table 80 of FIG. 6. If the drive is not locked, the process of steps 320-345 of FIG. 11 is conducted. If the device is locked, and not unlocked in step 412 of FIG. 12B, the requested event is conducted in step 425, and the tables are maintained unchanged in step 426, so that the drive thereby remains locked to the host application.

The steps of the above processes may be altered in sequence or combined and changed in detail as appropriate.

While the preferred embodiments of the present invention have been illustrated in detail, it should be apparent that modifications and adaptations to those embodiments may occur to one skilled in the art without departing from the scope of the present invention as set forth in the following claims. 

We claim:
 1. A virtualization system for directing communication between at least one host application and physical data storage drives of an automated data storage library, said library storing a plurality of portable data storage cartridges in storage shelves and transporting said portable data storage cartridges between said storage shelves and said physical data storage drives, comprising: at least one drive image provider coupled to said at least one host application, providing an image at least one fixed of virtual data storage drive to said at least one host application, providing a fixed identification and a fixed set of responses to said at least one host application for each of said at least one fixed virtual data storage drives; and directing communication between said at least one host application and physical data storage drives of a pool of “n” said physical data storage drives of said automated data storage library; and a drive resource provider coupled to said at least one drive image provider, at any one time, said drive resource provider assigning any number “m” of said pool of physical data storage drives to said virtual data storage drives, and “n”−“m” of said pool of physical data storage drives indicated as freed and available for assignment; said drive resource provider responding to a triggering event of said at least one host application requesting one of said virtual data storage drives, dedicating one of said “n”−“m” physical data storage drives of said pool to said one virtual data storage drive, providing an indication thereof for said drive image provider of said virtual physical data storage drive; said drive image provider characterizing said dedicated physical data storage drive to said requesting host application as said one fixed virtual drive, said drive image provider directing communication to said dedicated physical data storage drive by said requesting host application as said virtual data storage drive; and upon said requesting host application requesting a virtual data storage drive prior to said drive resource provider dedicating said physical data storage drive, said drive image provider characterizing said virtual data storage drive to said requesting host application as “not ready”.
 2. The virtualization system of claim 1, wherein said triggering event comprises a request by said requesting host application to mount a selected one of said portable data storage cartridges at a virtual data storage drive, and wherein said drive resource provider additionally indicates for said library that said selected portable data storage cartridge is to be mounted at said dedicated one of said “n”−“m” data storage drives of said pool.
 3. The virtualization system of claim 1, wherein said triggering event comprises a “RESERVE” request by said requesting host application for a virtual data storage drive of said drive image provider, said drive image provider notifying said drive resource provider of said request, and wherein said drive resource provider additionally indicates for said library that said dedicated physical data storage drive is dedicated to said virtual data storage drive for mounting any portable data storage cartridge selected for mounting at said virtual data storage drive.
 4. The virtualization system of claim 1, wherein said triggering event comprises a request by said requesting host application for a virtual data storage drive, and wherein said drive resource provider additionally indicates for said library that said dedicated physical data storage drive is dedicated to said virtual data storage drive for mounting any portable data storage cartridge selected for mounting at said virtual data storage drive.
 5. The virtualization system of claim 1, wherein said drive resource provider additionally responds to a detriggering event relating to said virtual data storage drive comprising said dedicated physical data storage drive, said drive resource provider indicating said physical data storage drive is freed from said virtual data storage drive, and added to said freed physical data storage drives of said pool.
 6. The virtualization system of claim 5, wherein said detriggering event comprises a command by said at least one host application to de mount said one of said portable data storage cartridges from said dedicated physical data storage drive, identified as one of said virtual data storage drives, and wherein said drive resource provider additionally provides an indication for said library that said one of said portable data storage cartridges is to be demounted.
 7. The virtualization system of claim 5, wherein said detriggering event comprises a command to said drive image provider by said at least one host application to release one of said virtual data storage drives, and wherein said drive image provider notifies said drive resource provider of said command.
 8. The virtualization system of claim 7, wherein said drive resource provider additionally notifies said library to demount any said portable data storage cartridge mounted at said dedicated physical data storage drive.
 9. The virtualization system of claim 5, wherein said detriggering event comprises non-use of said dedicated physical data storage drive for a predetermined time-out period.
 10. The virtualization system of claim 9, wherein, upon expiration of said predetermined time-out period, said drive resource provider additionally notifies said library to demount any said portable data storage cartridge mounted at said dedicated physical data storage drive.
 11. The virtualization system of claim 1, additionally comprising a plurality of virtual libraries, wherein at least one of said virtual libraries is assigned a higher priority, such that, upon “m”−“n” equaling zero, meaning that all of said physical data storage drives of said pool are dedicated, upon a triggering event for said higher priority virtual library, said drive resource provider deallocates a physical data storage drive from a lower priority said virtual library, notifies said drive image provider of said deallocation, notifies said library to demount any portable data storage cartridge from said deallocated physical data storage drive, and dedicates said deallocated physical data storage drive to said virtual data storage drive for said higher priority host application, and wherein said drive image provider characterizes said virtual data storage drive of said virtual data storage drive of said deallocated physical data storage drive to said host application of said lower priority virtual library as “not ready”.
 12. The virtualization system of claim 1, wherein said drive resource provider locks one of said physical data storage drives to one of said virtual data storage drives, such that said physical data storage drive is unavailable as a freed drive.
 13. The virtualization system of claim 1, wherein at least one of said physical data storage drives is added, deleted, exchanged in said pool of data storage drives of said drive resource provider, and wherein said drive image provider characterizes said virtual data storage drives as unchanged.
 14. The virtualization system of claim 13, wherein said drive image provider characterization comprises employing a same unique serial number for each of said unchanged virtual data storage drives.
 15. The virtualization system of claim 13, wherein said drive image provider characterization comprises employing a same address for each of said unchanged virtual data storage drives.
 16. The virtualization system of claim 1, wherein said drive image provider comprises a device driver of said at least one host application, and wherein said drive resource provider comprises a device driver of one of a plurality of said host applications.
 17. The virtualization system of claim 1, wherein said drive image provider comprises a device driver of said at least one host application, and wherein said drive resource provider comprises a component intermediate said at least one host application and said automated data storage library.
 18. The virtualization system of claim 1, wherein said drive image provider and said drive resource provider comprise a component intermediate said at least one host application and said automated data storage library.
 19. The virtualization system of claim 1, wherein said drive image provider comprises a device driver of said at least one host application, and wherein said drive resource provider comprises a component of said automated data storage library.
 20. The virtualization system of claim 1, wherein said drive image provider comprises a component intermediate said at least one host application and said automated data storage library, and wherein said drive resource provider comprises a component of said automated data storage library.
 21. A virtualization method for directing communication between at least one host application and physical data storage drives of an automated data storage library, said library storing a plurality of portable data storage cartridges in storage shelves and transporting said portable data storage cartridges between said storage shelves and said physical data storage drives, comprising the steps of: responding to said at least one host application, providing an image of at least one fixed virtual data storage drive, providing a fixed identification and a fixed set of responses to said at least one host application for each of said at least one fixed virtual data storage drives, and directing communication between said at least one host application and said physical data storage drives of said automated data storage library; providing a pool of “n” said physical data storage drives of said automated data storage library, at any one time, assigning any number “m” of said pool of physical data storage drives, and “n”−“m” of said pool of data storage drives indicated as freed and available for assignment; responding to a triggering event of said at least one host application requesting one of said virtual data storage drives, dedicating one of said “n”−“m” physical data storage drives of said pool to said one virtual data storage drive; characterizing said dedicated physical data storage drive to said requesting host application as said one fixed virtual drive, directing communication to said dedicated physical data storage drive by said requesting host application as said virtual data storage drive; and upon said requesting host application requesting a virtual data storage drive prior to said dedication step dedicating said physical data storage drive, characterizing said virtual data storage drive to said requesting host application as “not ready”.
 22. The virtualization method of claim 21, wherein said triggering event comprises a request by said requesting host application to mount a selected one of said portable data storage cartridges at a virtual data storage drive, and wherein said method additionally comprises the step of indicating for said library that said selected portable data storage cartridge is to be mounted at said dedicated one of said “n”−“m” data storage drives of said pool.
 23. The virtualization method of claim 21, wherein said triggering event comprises a “RESERVE” request by said requesting host application for a virtual data storage drive, and wherein said method additionally comprises the step of indicating for said library that said dedicated physical data storage drive is dedicated to said virtual data storage drive for mounting any portable data storage cartridge selected for mounting at said virtual data storage drive.
 24. The virtualization method of claim 21, wherein said triggering event comprises a request by said requesting host application for a virtual data storage drive, and wherein said method additionally comprises the step of indicating to said library that said dedicated physical data storage drive is dedicated to said virtual data storage drive for mounting any portable data storage cartridge selected for mounting at said virtual data storage drive.
 25. The virtualization method of claim 21, additionally comprising the step of responding to a detriggering event relating to said virtual data storage drive comprising said dedicated physical data storage drive, indicating said physical data storage drive is freed from said virtual data storage drive, and added to said freed physical data storage drives of said pool.
 26. The virtualization method of claim 25, wherein said detriggering event comprises a command by said at least one host application to demount said one of said portable data storage cartridges from said dedicated physical data storage drive, identified as one of said virtual data storage drives, and wherein said method additionally comprises the step of indicating for said library that said one of said portable data storage cartridges is to be demounted.
 27. The virtualization method of claim 25, wherein said detriggering event comprises a command by said at least one host application to release one of said virtual data storage drives, and wherein said method additionally comprises the step of indicating which one of said dedicated physical data storage drives is represented as said virtual data storage drive for freeing said indicated physical data storage drive from said virtual data storage drive, and adding said indicated physical data storage drive to said freed physical data storage drives of said pool.
 28. The virtualization method of claim 27, wherein said method additionally comprises the step of notifying said library to demount any said portable data storage cartridge mounted at said dedicated physical data storage drive.
 29. The virtualization method of claim 25, wherein said detriggering event comprises non-use of said dedicated physical data storage drive for a predetermined time-out period.
 30. The virtualization method of claim 29, wherein, upon expiration of said predetermined time-out period, said method additionally comprises the step of notifying said library to demount any said portable data storage cartridge mounted at said dedicated physical data storage drive.
 31. The virtualization method of claim 21, wherein said library comprises a plurality of virtual libraries, said method additionally comprising the steps of: assigning at least one of said virtual libraries a higher priority; and upon “m”−“n” equaling zero, meaning that all of said physical data storage drives are dedicated, and upon a triggering event for said higher priority virtual library, deallocating a physical data storage drive from a lower priority said virtual library, notifying said library to demount any portable data storage cartridge from said deallocated physical data storage drive, and dedicating said deallocated physical data storage drive to said virtual data storage drive for said higher priority host application, characterizing said virtual data storage drive of said deallocated physical data storage drive to said host application as “not ready”.
 32. The virtualization method of claim 21, additionally comprising the step of locking one of said physical data storage drives to one of said virtual data storage drives, such that said data storage drive is unavailable as a freed drive.
 33. The virtualization method of claim 21, additionally comprising the steps of: adding, deleting, exchanging at least one of said physical data storage drives in said pool of physical data storage drives; and characterizing said virtual data storage drives as unchanged.
 34. The virtualization method of claim 33, wherein said step of characterizing said virtual drives comprises employing a same unique serial number for each of said unchanged virtual data storage drives.
 35. The virtualization method of claim 33, wherein said step of characterizing said virtual drives comprises employing a same address for each of said unchanged virtual data storage drives.
 36. A computer program product of a computer readable medium usable with a programmable computer, said computer program product having computer readable program code embodied therein for directing virtualized communication between at least one host application and physical data storage drives of an automated data storage library, said library storing a plurality of portable data storage cartridges in storage shelves and transporting said portable data storage cartridges between said storage-shelves and said physical data storage drives, said at least one host application coupled to said automated data storage library, comprising: computer readable program code which causes a computer processor to respond to said at least one host application, providing an image of at least one fixed virtual drive, providing a fixed identification and a fixed set of responses to said at least one host application for each of said at least one fixed virtual data storage drives, directing communication between said at least one host application and physical data storage drives of said automated data storage library; computer readable program code which causes a computer processor to identify a pool of “n” said physical data storage drives of said automated data storage library, at any one time, assigning any number “m” of said pool of physical data storage drives, and “n”−“m” of said pool of physical data storage drives indicated as freed and available for assignment; computer readable program code which causes a computer processor to respond to a triggering event of said at least one host application requesting one of said virtual data storage drives, dedicating one of said “n”−“m” physical data storage drives of said pool to said one virtual data storage drive; computer readable program code which causes a computer processor to characterize said dedicated physical data storage drive to said requesting host application as said one fixed virtual drive, directing communication to said dedicated physical data storage drive by said requesting host application as said virtual data storage drive; and computer readable program code which causes a computer processor, upon said requesting host application requesting a virtual data storage drive prior to said dedication of said physical data storage drive, to characterize said virtual data storage drive to said requesting host application as “not ready”.
 37. The computer program product of claim 36, wherein said triggering event comprises a request by said requesting host application to mount a selected one of said portable data storage cartridges at a virtual data storage drive, and wherein said computer program product additionally comprises computer readable program code which causes a computer processor to indicate for said library that said selected portable data storage cartridge is to be mounted at said dedicated one of said “n”−“m” data storage drives of said pool.
 38. The computer program product of claim 36, wherein said triggering event comprises a “RESERVE” request by said requesting host application to said drive image provider for a virtual data storage drive, and wherein said computer program product additionally comprises computer readable program code which causes a computer processor to indicate for said library that said dedicated physical data storage drive is dedicated to said virtual data storage drive for mounting any portable data storage cartridge selected for mounting at said virtual data storage drive.
 39. The computer program product of claim 36, wherein said triggering event comprises a request by said triggering host application for a virtual data storage drive, and wherein said computer program product additionally comprises computer readable program code which causes a computer processor to indicate for said library that said dedicated physical data storage drive is dedicated to said virtual data storage drive for mounting any portable data storage cartridge selected for mounting at said virtual data storage drive.
 40. The computer program product of claim 36, additionally comprising computer readable program code which causes a computer processor to respond to a detriggering event relating to said virtual data storage drive comprising said dedicated physical data storage drive, said computer readable program code causing a computer processor to indicate said physical data storage drive is freed from said virtual data storage drive, and added to said freed physical data storage drives of said pool.
 41. The computer program product of claim 40, wherein said detriggering event comprises a command by said at least one host application to demount said one of said portable data storage cartridges from said dedicated physical data storage drive, identified as one of said virtual data storage drives, and wherein said computer program product additionally comprises computer readable program code which causes a computer processor to indicate for said library that said one of said portable data storage cartridges is to be demounted.
 42. The computer program product of claim 40, wherein said detriggering event comprises a command by said at least one host application to release one of said virtual data storage drives, and wherein said computer program product additionally comprises computer readable program code which causes a computer processor to indicate which one of said dedicated physical data storage drives is represented as said virtual data storage drive for freeing said indicated physical data storage drive from said virtual data storage drive, and adding said indicated physical data storage drive to said freed physical data storage drives of said pool.
 43. The computer program product of claim 42, wherein said computer program product additionally comprises computer readable program code which causes a computer processor to notify said library to demount any said portable data storage cartridge mounted at said dedicated physical data storage drive.
 44. The computer program product of claim 40, wherein said detriggering event comprises non-use of said dedicated physical data storage drive for a predetermined time-out period.
 45. The computer program product of claim 44, wherein said computer program product additionally comprises: computer readable program code which causes a computer processor to, upon expiration of said predetermined time-out period, notify said library to demount any said portable data storage cartridge mounted at said dedicated physical data storage drive.
 46. The computer program product of claim 36, wherein said library comprises a plurality of virtual libraries, and wherein said computer program product additionally comprises: computer readable program code which causes a computer processor to assign at least one of said virtual libraries a higher priority; and computer readable program code which causes a computer processor to, upon “m”−“n” equaling zero, meaning that all of said physical data storage drives are dedicated, and upon a triggering event for said higher priority virtual library, deallocate a physical data storage drive from a lower priority said virtual library, notifying said library to demount any portable data storage cartridge from said deallocated physical data storage drive, and dedicate said deallocated physical data storage drive to said virtual data storage drive for said higher priority host application, characterizing said virtual data storage drive of said deallocated physical data storage drive to said host application as “not ready”.
 47. The computer program product of claim 36, additionally comprising computer readable program code which causes a computer processor to lock one of said physical data storage drives to one of said virtual data storage drives, such that said data storage drive is unavailable as a freed drive.
 48. The computer program product of claim 36, additionally comprising: computer readable program code which causes a computer processor to identify the addition, deletion, exchange of at least one of said physical data storage drives in said pool of physical data storage drives; and computer readable program code which causes a computer processor to characterize said virtual data drives as unchanged.
 49. The computer program product of claim 48, wherein said computer readable program code which causes a computer processor to characterize said virtual drives, comprises computer readable program code which causes a computer processor to employ a same unique serial number for each of said unchanged virtual data storage drives.
 50. The computer program product of claim 48, wherein said computer readable program code which causes a computer processor to characterize said virtual drives, comprises computer readable program code which causes a computer processor to employ a same address for each of said unchanged virtual data storage drives.
 51. The computer program product of claim 36, wherein said computer readable program code additionally provides at least one drive image table comprising a list of at least said virtual data storage drives comprising said one image, and, for each said virtual data storage drive, said fixed identification, and an identification of any said physical data storage drive of said pool dedicated as said virtual data storage drive.
 52. The computer program product of claim 51, wherein said computer readable program code which causes a computer processor to characterize said dedicated physical data storage drive, comprises computer readable code to consult said drive image table to characterize said dedicated data storage drive to said requesting host application as one of said fixed virtual data storage drives, directing communication to said dedicated data storage drive by said requesting host application as one of said fixed plurality of virtual data storage drives.
 53. An automated data storage library, coupled to at least one host application, comprising: a plurality of physical data storage drives; a plurality of storage shelves for storing a plurality of portable data storage cartridges; an accessor robot for transporting said portable data storage cartridges between said storage shelves and said physical data storage drives; a robot control for operating said accessor robot; at least one drive image provider coupled to said at least one host application, providing an image of at least one fixed virtual data storage drive, providing a fixed identification and a fixed set of responses to said at least one host application for each of said at least one fixed virtual data storage drives, and for directing communication between said at least one host application and physical data storage drives of a pool of “n” said physical data storage drives; and a drive resource provider coupled to said at least drive image provider, at any one time, said drive resource provider assigning any number “m” of said pool of physical data storage drives to said virtual data storage drives, and “n”−“m” of said pool of physical data storage drives indicated as freed and available for assignment; said drive resource provider responding to a triggering event of said at least one host application requesting one of said virtual data storage drives, dedicating one of said “n”−“m” physical data storage drives of said pool to said one virtual data storage drive, providing an indication thereof for said drive image provider of said virtual data storage drive; said drive image provider characterizing said dedicated physical data storage drive to said requesting host application as said one fixed virtual drive, said drive image provider directing communication to said dedicated physical data storage drive by said requesting host application as said virtual data storage drive; and upon said requesting host application requesting a virtual data storage drive prior to said drive resource provider dedicating said physical data storage drive, said drive image provider characterizing said virtual data storage drive to said requesting host application as “not ready”.
 54. The automated data storage library of claim 53, wherein said triggering event comprises a request by said requesting host application to mount a selected one of said portable data storage cartridges at a virtual data storage drive, and wherein said drive resource provider additionally indicates for said robot control that said selected portable data storage cartridge is to be mounted at said dedicated one of said “n”−“m” data storage drives of said pool.
 55. The automated data storage library of claim 53, wherein said triggering event comprises a “RESERVE” request by said requesting host application for a virtual data storage drive of said drive image provider, said drive image provider notifying said drive resource provider of said request, and wherein said drive resource provider additionally indicates for said robot control that said dedicated physical data storage drive is dedicated to said virtual data storage drive for mounting any portable data storage cartridge selected for mounting at said virtual data storage drive.
 56. The automated data storage library of claim 53, wherein said triggering event comprises a request by said requesting host application for a virtual data storage drive, and wherein said drive resource provider additionally indicates for said robot control that said dedicated physical data storage drive is dedicated to said virtual data storage drive for mounting any portable data storage cartridge selected for mounting at said virtual data storage drive.
 57. The automated data storage library of claim 53, wherein said drive resource provider additionally responds to a detriggering event relating to said virtual data storage drive comprising said dedicated physical data storage drive, said drive resource provider indicating said physical data storage drive is freed from said virtual data storage drive, and added to said freed physical data storage drives of said pool.
 58. The automated data storage library of claim 57, wherein said detriggering event comprises a command by said at least one host application to demount said one of said portable data storage cartridges from said dedicated physical data storage drive, identified as one of said virtual data storage drives, and wherein said drive resource provider additionally provides an indication for said robot control that said one of said portable data storage cartridges is to be demounted.
 59. The automated data storage library of claim 57, wherein said detriggering event comprises a command to said drive image provider by said at least one host application to release one of said virtual data storage drives, and wherein said drive image provider notifies said drive resource provider of said command.
 60. The automated data storage library of claim 59, wherein said drive resource provider additionally notifies said robot control to demount any said portable data storage cartridge mounted at said dedicated physical data storage drive.
 61. The automated data storage library of claim 57, wherein said detriggering event comprises non-use of said dedicated physical data storage drive for a predetermined time-out period.
 62. The automated data storage library of claim 61, wherein, upon expiration of said predetermined time-out period, said drive resource provider additionally notifies said robot control to demount any said portable data storage cartridge mounted at said dedicated physical data storage drive,.
 63. The automated data storage library of claim 53, additionally comprising a plurality of virtual libraries, wherein at least one of said virtual libraries is assigned a higher priority, such that, upon “m”−“n” equaling zero, meaning that all of said physical data storage drives of said pool are dedicated, upon a triggering event for said higher priority virtual library, said drive resource provider deallocates a physical data storage drive from a lower priority said virtual library, notifies said drive image provider of said deallocation, notifies said robot control to demount any portable data storage cartridge from said deallocated physical data storage drive, and dedicates said deallocated physical data storage drive to said virtual data storage drive for said higher priority host application, and wherein said drive image provider characterizes said virtual data storage drive of said deallocated physical data storage drive to said host application as “not ready”.
 64. The automated data storage library of claim 53, wherein said drive resource provider locks one of said physical data storage drives to one of said virtual data storage drives, such that said physical data storage drive is unavailable as a freed drive.
 65. The automated data storage library of claim 53, wherein at least one of said physical data storage drives is added, deleted, exchanged in said pool of data storage drives of said drive resource provider, and wherein said drive image provider characterizes said virtual data storage drives as unchanged.
 66. The automated data storage library of claim 65, wherein said drive image provider characterization comprises employing a same unique serial number for each of said unchanged virtual data storage drives.
 67. The automated data storage library of claim 65, wherein said drive image provider characterization comprises employing a same address for each of said unchanged virtual data storage drives.
 68. A virtualization system for directing communication between at least one host application and physical data storage drives of an automated data storage library, said library storing a plurality of portable data storage cartridges in storage shelves and transporting said portable data storage cartridges between said storage shelves and said physical data storage drives, comprising: a drive resource provider providing at least one drive image table comprising a list of virtual data storage drives providing an image of a fixed plurality of said virtual data storage drives, and, for each said virtual data storage drive, a fixed identification; at any one time, said drive resource provider assigning any number “m” of physical data storage drives of a pool of “n” said physical data storage drives of said automated data storage library, and “n”−“m” of said pool of data storage drives indicated as freed and available for assignment; said drive resource provider responding to a triggering event of said at least one host application requesting one of said virtual data storage drives, dedicating one of said “n”−“m” physical data storage drives of said pool to said one virtual data storage drive, identifying said dedicated physical data storage drive in said drive image table as said one virtual data storage drive; and at least one drive image provider coupled to said at least one host application and coupled to said drive resource provider, providing at least one image of said fixed virtual data storage drives to said at least one host application, said image derived from a corresponding said drive image table, said drive image provider providing said fixed identification and fixed set of responses to said at least one host application for each of said fixed plurality of virtual drives; and directing communication between said at least one host application and said physical data storage drives of said pool of physical data storage drives of said automated data storage library; said drive image provider responding to said dedication and identification of said physical data storage drive in said drive image table, characterizing said dedicated physical data storage drive to said requesting host application as one of said fixed virtual data storage drives, and directing communication between said dedicated data storage drive and said requesting host application as said virtual data storage drive; and upon said requesting host application requesting a virtual data storage drive prior to said drive resource provider dedicating said physical data storage drive, said drive image provider characterizing said virtual data storage drive to said requesting host application as “not ready”.
 69. The virtualization system of claim 68, wherein said drive resource provider additionally responds to a detriggering event relating to said virtual data storage drive comprising said dedicated physical data storage drive, said drive resource provider deleting said physical data storage drive assignment to said virtual data storage drive in said drive image table, and indicating said physical data storage drive is added to said freed physical data storage drives of said pool.
 70. The virtualization system of claim 69, wherein said drive resource provider additionally is coupled to said physical data storage drives of said pool and determines time of non-use of each of said dedicated physical data storage drives, said detriggering event comprising non-use of a said dedicated physical data storage drive for a predetermined time-out period.
 71. The virtualization system of claim 68, wherein at least one of said physical data storage drives is added, deleted, exchanged in said pool of physical data storage drives of said drive resource provider, and wherein said drive image table identifies said virtual data storage drives as unchanged.
 72. The virtualization system of claim 71, wherein said drive image table fixed identification comprises a same unique serial number for each of said unchanged virtual data storage drives.
 73. The virtualization system of claim 71, wherein said drive image table fixed identification comprises a same address for each of said unchanged virtual data storage drives.
 74. A virtualization method for directing communication between at least one host application and physical data storage drives of an automated data storage library, said library storing a plurality of portable data storage cartridges in storage shelves and transporting said portable data storage cartridges between said storage shelves and said physical data storage drives, comprising the steps of: providing at least one drive image table comprising a list of virtual data storage drives providing an image of a fixed plurality of said virtual data storage drives, and, for each said virtual data storage drive, a fixed identification; responding to said at least one host application, providing at least one image of said fixed virtual data storage drives to said at least one host application, said image derived from a corresponding said drive image table, providing said fixed identification and fixed set of responses to said at least one host application for each of said fixed virtual data storage drives; and directing communication between said at least one host application and said plurality of physical data storage drives of said automated data storage library; providing a pool of “n” said physical data storage drives of said automated data storage library, at any one time, assigning any number “m” of said pool of physical data storage drives, and “n”−“m” of said pool of physical data storage drives indicated as freed and available for assignment; responding to a triggering event of said at least one host application requesting one of said virtual data storage drives, dedicating one of said “n”−“m” physical data storage drives of said pool to said one virtual data storage drive, identifying said dedicated physical data storage drive in said drive image table as said one virtual data storage drive; responding to said dedication and identification of said physical data storage drive in said drive image table, characterizing said dedicated physical data storage drive to said requesting host application as one of said fixed virtual data storage drives, directing communication between said dedicated physical data storage drive and said requesting host application as said virtual data storage drive; and upon said requesting host application requesting a virtual data storage drive prior to said dedication step dedicating said physical data storage drive, characterizing said virtual data storage drive to said requesting host application as “not ready”.
 75. The virtualization method of claim 74, additionally comprising the steps of: adding, deleting, exchanging at least one of said physical data storage drives in said pool of physical data storage drives; and maintaining said drive image table to identify said virtual data storage drives as unchanged.
 76. An automated data storage library, coupled to at least one host application, comprising: a plurality of physical data storage drives; a plurality of storage shelves for storing a plurality of portable data storage cartridges; an accessor robot for transporting said portable data storage cartridges between said storage shelves and said physical data storage drives; a robot control for operating said accessor robot; a drive resource provider providing at least one drive image table comprising a list of virtual data storage drives providing an image of a fixed plurality of said virtual data storage drives, and, for each said virtual data storage drive, a fixed identification; at any one time, said drive resource provider assigning any number “m” of physical data storage drives of a pool of “n” said physical data storage drives, and “n”−“m” of said pool of data storage drives indicated as freed and available for assignment; said drive resource provider responding to a triggering event of said at least one host application requesting one of said virtual data storage drives, dedicating one of said “n”−“m” physical data storage drives of said pool to said one virtual data storage drive, identifying said dedicated physical data storage drive in said drive image table as one said of virtual data storage drive; and at least one drive image provider coupled to said at least one host application and coupled to said drive resource provider, providing at least one image of said fixed virtual data storage drives to said at least one host application, said image derived from a corresponding said drive image table, said drive image provider providing said fixed identification and fixed set of responses to said at least one host application for each of said fixed plurality of virtual drives; and directing communication between said at least one host application and said physical data storage drives of said pool of physical data storage drives; said drive image provider responding to said dedication and identification of said physical data storage drive in said drive image table, characterizing said dedicated physical data storage drive to said requesting host application as one of said fixed data storage virtual data storage drives, and directing communication between said dedicated physical data storage drive and said requesting host application as said virtual data storage drive; and upon said requesting host application requesting a virtual data storage drive prior to said drive resource provider dedicating said physical data storage drive, said drive image provider characterizing said virtual data storage drive to said requesting host application as “not ready”.
 77. The automated data storage library of claim 76, wherein said library is arranged to comprise a plurality of virtual library partitions, each assigned a plurality of said storage shelves, and each assigned to at least one of said host applications; and wherein said drive resource provider additionally provides a library image table comprising an updated listing indicating any said physical data storage drives of said virtual library partition, and indicating said storage shelves dedicated to said at least one host application of said virtual library partition.
 78. The automated data storage library of claim 77, wherein each of said virtual library partitions is assigned a relative priority, and wherein said drive resource provider, upon “m”−“n” equaling zero for said higher priority virtual library partition, meaning that all of said physical data storage drives are dedicated, deallocates a physical data storage drive from a lower priority virtual library partition and allocates said physical data storage drive to said virtual library partition having said higher priority. 